A circuit for obtaining information on a physical quantity according to an embodiment includes a sensor arrangement sensitive to the physical quantity, at least one further sensor element sensitive to the physical quantity and a supply circuit configured to provide the sensor arrangement with a supply signal comprising a supply voltage controlled by the supply circuit in a closed-loop configuration. The supply circuit is further configured to provide the at least one further sensor element with a further supply signal comprising a further supply current such that a magnitude of the further supply current fulfills a predetermined relationship with a magnitude of a supply current of the supply signal. As a consequence, it may be possible to improve a trade-off between an improved compensation of variations, simplifying an implementation, simplifying the manufacturing, simplifying the sensing and providing stable sensing conditions.
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13. A method for obtaining information on a physical quantity, the method comprising:
providing a sensor arrangement with a supply signal comprising a supply voltage controlled by a supply circuit in a closed-loop configuration, the sensor arrangement being sensitive to the physical quantity;
providing, by the sensor arrangement, a feedback signal to the supply circuit to regulate the supply signal based on operational conditions of the sensor arrangement; and
providing, by a current mirror of the sensor circuit, a single sensor element with a further supply signal having a further supply current such that a magnitude of the further supply current is a replicated current and proportional to a magnitude of a supply current of the supply signal, wherein the single sensor element is sensitive to the physical quantity.
1. A circuit for obtaining information on a physical quantity, the circuit comprising:
a sensor arrangement sensitive to the physical quantity;
a single sensor element sensitive to the physical quantity; and
a supply circuit configured to provide the sensor arrangement with a supply signal having a supply voltage controlled by the supply circuit in a closed-loop configuration,
wherein the sensor arrangement is configured to provide a feedback signal to the supply circuit to regulate the supply signal based on operational conditions of the sensor arrangement, and
wherein the supply circuit comprises a current mirror configured to provide the single sensor element with a further supply signal having a further supply current such that a magnitude of the further supply current is a replicated current and proportional to a magnitude of a supply current of the supply signal.
14. A sensor for obtaining information on a physical quantity, the sensor comprising:
a sensor arrangement sensitive to the physical quantity;
a single sensor element sensitive to the physical quantity;
a supply circuit configured to provide the sensor arrangement with a supply signal having a supply voltage controlled by the supply circuit in a closed-loop configuration,
wherein the sensor arrangement is configured to provide a feedback signal to the supply circuit to regulate the supply signal based on operational conditions of the sensor arrangement and
wherein the supply circuit comprises a current mirror configured to provide the single sensor element with a further supply signal having a further supply current such that a magnitude of the further supply current is a replicated current and proportional to a magnitude of a supply current of the supply signal; and
a detection circuit coupled to the single sensor element and configured to generate an output signal indicative of the information on the physical quantity.
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Embodiments relate to a circuit, a method and a sensor for obtaining information on a physical quantity.
Many applications rely on sensing a physical quantity such as a magnetic quantity, a temperature, a pressure, a physical quantity related to electromagnetic radiation or a mechanical exposure, to name just a few. The applications come from all fields of technology. For instance, some applications come from measuring a rotation speed and a rotation direction of a wheel of a motorized vehicle, a steering angle, or the like. These measurements may, for instance, be carried out using magnetic field sensor elements, optical sensor elements or other sensor elements, such as sensor elements sensitive to a mechanical stress.
Due to the widespread application of these sensors, expectations exist to simplify their manufacturing and implementation to reduce, for instance, costs associated with these devices. However, in many applications also reliability as well as accuracy are of at least some importance. Sources for inaccuracies come, for instance, from deviations from stable sensing conditions as well as variations such as temperature-related or process-related variations to name just two examples.
Therefore, a demand exists to improve a trade-off between an improved compensation of variations, simplifying an implementation, simplifying the manufacturing, simplifying the sensing and providing stable sensing conditions.
A circuit for obtaining information on a physical quantity according to an embodiment comprises a sensor arrangement sensitive to a physical quantity and at least one further sensor element sensitive to the physical quantity. The circuit according to an embodiment further comprises a supply circuit configured to provide the sensor arrangement with a supply signal comprising a supply voltage controlled by the supply circuit in a closed-loop configuration. The supply circuit is further configured to provide the at least one further sensor element with a further supply signal comprising a further supply current such that a magnitude of the further supply current fulfills a predetermined relationship with a magnitude of a supply current of the supply signal.
A method for obtaining information on a physical quantity comprises providing a sensor arrangement with a supply signal comprising a supply voltage controlled by the supply circuit in a closed-loop configuration, wherein the sensor arrangement is sensitive to a physical quantity. It further comprises providing at least one further sensor element with a further supply signal comprising a further supply current such that a magnitude of the further supply current fulfills a predetermined relationship with a magnitude of a supply current of the supply signal, wherein the at least one further signal element is sensitive to the physical quantity.
Several embodiments of the present invention will be described in the enclosed Figures.
In the following, embodiments according to the present invention will be described in more detail. In this context, summarizing reference signs will be used to describe several objects simultaneously or to describe common features, dimensions, characteristics, or the like of these objects. The summarizing reference signs are based on their individual reference signs. Moreover, objects appearing in several embodiments or several figures, but which are identical or at least similar in terms of at least some of their functions or structural features, will be denoted with the same or similar reference signs. To avoid unnecessary repetitions, parts of the description referring to such objects also relate to the corresponding objects of the different embodiments or the different figures, unless explicitly or—taking the context of the description and the figures into account—implicitly stated otherwise. Therefore, similar or related objects may be implemented with at least some identical or similar features, dimensions, and characteristics, but may be also implemented with differing properties.
In today's world, sensors for physical quantities are widely used in different fields of applications. The sensors involved are used to detect different physical quantities such as magnetic field-related or electromagnetic-related physical quantities as well as temperatures, pressures, mechanical stresses and the like. Depending on the application, different requirements, specification and boundary conditions are set. Among these, accuracy, reliability and availability often interact with each other leading to at least sometimes contradictory design goals. For instance, availability and, therefore, a widespread implementation of such sensor may make an easy manufacturing and implementation of the sensors attractive. However, just following these design goals, may unfavorably lead to less reliable and/or less accurate sensors.
For instance, to improve an accuracy of such a sensor, it may be interesting to implement an improved compensation of variations, such as temperature variations or process variations. Moreover, it may be desirable to enable sensors to operate under more stable sensing conditions and to simplify the sensing process.
Therefore, a demand exists to improve a trade-off between a compensation of variations concerning a sensor, simplifying its manufacturing process and implementation, providing stable sensing conditions and simplifying the sensing process. As will be outlined below in more detail, embodiments may provide the opportunity of improving the aforementioned trade-off.
The sensor 100 comprises a circuit 110 for obtaining information on a physical quantity. The physical quantity may, for instance, be a strength of a magnetic field, a direction of a magnetic field, a strength of a component of a magnetic field, a temperature, a pressure, an intensity of an electromagnetic radiation, a frequency of an electromagnetic radiation, a wavelength of the electromagnetic radiation and a mechanical exposure or stress.
The circuit 110 comprises a sensor arrangement 120, which is sensitive to the physical quantity as well as at least one further sensor element 130, which is also sensitive to the physical quantity. The embodiment shown in
The circuit 110 further comprises a supply circuit 140, which is configured to provide the sensor arrangement 120 with a supply signal SS1 comprising a supply voltage controlled by the supply circuit 140 in a closed-loop configuration. In the embodiment shown in
However, before describing possible implementations of the closed-feedback loop in more detail, the circuit 110 will be described first. The supply circuit 140 is further configured to provide the at least one further sensor element 130 with a further supply signal SS2 comprising a further supply current such that a magnitude of the further supply current fulfills a predetermined relationship with a magnitude of the supply current of the supply signal SS1. By using a supply circuit 140 as outlined, it may be possible to improve the aforementioned trade-off by provided the further sensor element 130 with a supply current depending on the operational conditions of the sensor arrangement 120. In other words, the further supply signal SS2 is provided to the further sensor element 130 taking influences on the sensor element 120 at least partially into account. For instance, an influence on the sensor 100 and its sensor elements caused by temperature variations, process variations or other variations may therefore be at least partially compensated.
To put it in different terms, the further supply signal SS2 comprises a not-regulated voltage or in yet other words, a voltage created in an open loop. It is not to be intended to be kept at a constant value.
The further supply signal SS2 may optionally be provided such that the magnitude of the further supply current is essentially proportional to the magnitude of the supply current of the supply signal SS1. The further supply current may be, for instance, a proportional copy of the supply current provided to the sensor arrangement 120. As a consequence, it may be possible to implement the supply circuit 140 in a simple and efficient way.
For instance, as will be outlined in more detail below, the supply circuit may optionally comprise a current mirror configured to provide the further supply signal with the magnitude of the further current based on the magnitude of a supply current of a supply signal.
The supply signal SS1 and the further supply signal SS2 may both comprise alternating and/or direct contributions. For instance, both supply signals SS1, SS2 may comprise AC- (alternating current) and/or DC-components (direct current).
Returning to the closed-loop configuration for providing the supply signal SS1, the supply circuit 140 may be optionally configured to keep the magnitude of the supply voltage of the supply signal SS1 essentially constant. In the embodiment shown in
The sensor 100 or the circuit 110 may optionally comprise a detection circuit 170 coupled to the at least one sensor element 130 and configured to generate an output signal OS indicative of the additional information on the physical quantity to be determined. In the embodiment shown in
As mentioned before, the embodiment shown in
Returning to the sensor arrangement 120, it is to be noted that the sensor arrangement 120 may be configured to generate a signal, which is indicative of a spatial change of the physical quantity with respect to a direction 190. To illustrate this, in the lower part of
The sensor arrangement 120 may optionally comprise a single sensor element 200 capable of detecting such a spatial change of the physical quantity as illustrated in
To be more precise, in the embodiment shown in
Here, the sensor elements 200 are arranged to form half bridges 210-1, 210-2. The two half bridges 210 each comprise at least two sensor elements 200-1, 200-2 and 200-3, 200-4, respectively, as well as a node 220-1, 220-2, respectively, coupled between the at least two sensor elements 200. The signal indicative of the spatial change of the physical quantity is obtainable at the nodes 220 of the half bridges 210.
The two half bridges of the circuit 110 and the sensor 100 shown in
Due to the arrangement of the sensor elements 200, along the direction 190, the signals obtainable at the nodes 220 of the respective half bridges 210 may be considered to be indicative of a difference of the physical quantities BR and BL and, hence, indicative of the differential quantity BR-BL. In other words, at the node 220 a differential signal depending on BR-BL shows up. It is to be noted that the rightmost arrow shown in the lower part of
As a consequence, the current SS1 provided by the supply circuit 140 may be dependent on the physical quantity sensed by the sensor elements 200-1, . . . , 200-4. Hence, information on an average value 230 of the physical quantity acting on these sensor elements 200 of the sensor arrangement 120 may be comprised in the current SS1. Depending on the physical quantity to be sensed, the sensor elements 200 as well as the further sensor elements 130 may be any sensor element capable of detecting the respective physical quantity. For instance, the sensor elements 200 as well as the further sensor element 130 may be a magnetic field sensor element, a temperature sensor element, a pressure sensor element, a light-detecting sensor element or a sensor element being sensitive to mechanical exposure or stress.
To name just a few examples, a magnetic field-sensitive sensor element may, for instance, comprise an anisotropic magneto-resistive sensor element (AMR), a giant magneto-resistive sensor element (GMR), a tunneling magneto-resistive sensor element (TMR), a colossal magneto-resistive sensor element (CMR), an extraordinary magneto-resistive sensor element (EMR), a lateral Hall sensor element or a vertical Hall sensor element. Naturally, it may also be a pressure sensor, a temperature sensor, or the like, when other physical quantities are to be detected. Naturally, the physical quantity to be detected may be affected by another physical quantity allowing an indirect measurement of the physical quantity. For instance, although the sensor elements 200, 130 used are sensitive to a specific physical influence and, hence, physical quantity, the physical quantity to be sensed or measured may only indirectly influence the sensor elements 130, 200 to cause the physical influence detectable by the respective sensor elements 130, 200.
Both, the sensor arrangement 120 and the at least one further sensor element 130 is furthermore coupled to a terminal 240 for a reference potential, such as ground. It should be noted that the at least one further sensor element 130 is only provided with the further supply signal SS2. In other words, the further sensor elements 130 are not biased with additional components in the embodiment shown in
The sensor element arrangement 120 may comprise resistive sensor elements 200, which change their current consumption due to the average value 230 of the physical quantity acting on the respective sensor elements 200. Naturally, the same may also apply to the further sensor element 130 or the further sensor elements 130 to which the further supply signal SS2 is supplied.
When the average value 230 of the physical quantity acting on the sensor elements 200 of the sensor arrangement 120 is changed, due to the closed-loop configuration providing the essentially constant supply voltage of the supply signal SS1 the supply current of the supply signal SS1 is changed accordingly to keep the supply voltage of the supply signal SS1 essentially constant.
Since the further supply current of the further supply signal SS2 and the supply current of the supply signal SS1 fulfill the predetermined relationship, the change of the physical quantity leading to the change of the average value 230 will be at least partially transferred to the further supply signal SS2 of the further sensor element 130, for instance, by providing a proportional copy of the supply current. As a consequence, the detection circuit 170 may, for instance, be capable of detecting at the second node 130 a voltage indicative of a difference of the average value 230 of the physical quantity and the physical quantity acting on the further sensor element 130.
Optionally, the detection circuit 170 may also be coupled to the sensor arrangement 120, for instance, to the nodes 220-1, 220-2 of the half bridges 210-1, 210-2, respectively, to enable the detection circuit 170 to detect and optionally to process the signals provided by the half bridges 210. In this case, the output signal OS may further be indicative of the average value 230 acting on the sensor elements 200 of the sensor arrangement 120, a gradient or another spatial dependency or change of the physical quantity along direction 190.
However, it is to be noted that the operations described are by far not required to be carried out in the described order. The order of the operations may, for instance, be changed, at least partially timely overlapping or carried out simultaneously. The operations may also be processed repeatedly as a whole or at least partially.
As outlined before, sensors are used in a large variety of technical applications. In some of the applications, not only detecting the actual physical quantity or a spatial change along the direction 190 is of interest, but also a detection of a speed or a movement of the physical quantity in relation to the sensor or its sensor elements. Examples come, for instance, from the fields of detecting a rotation of a wheel such as a wheel of a car or another motorized vehicle, detecting a steering angle, a change thereof or similar applications.
An important challenge to be solved in this context is the detection of the speed and direction of a movement of a typically inhomogeneous physical quantity relative to the sensor. The sensor elements of the sensor are typically sensitive to the respective physical quantity and may, for instance, deliver a single-ended output signal proportional to the physical quantity or having another functional dependency with respect to the physical quantity. In contrast to a differential output signal, the sensor elements often merely provide a signal indicative of the physical quantity rather than a difference, a gradient or the like of the physical quantity.
To detect speed and direction of a movement, an arrangement of more than a single sensor element is, therefore, often used. Examples or applications come, but are by far not limited to the detection of rotation of a magnetic pole wheel or tooth wheel, a detection of a heat wave or the detection of a pressure wave to name just a few.
In the case of a detection of a rotation of a magnetic pole wheel or tooth wheel, the sensor elements may, for instance, be giant magneto-resistive sensor elements (GMR) and the associated physical quantity a moving or modulated magnetic field in terms of strength and/or direction. In the case of a detection of a heat wave, the sensor elements may be temperature-dependent resistors and the temperature the physical quantity to be sensed. Accordingly, in the case of detection of a pressure wave, the sensor elements may be pressure-dependent capacitances with the physical quantity being the pressure.
Solutions exist for sensor elements delivering a differential output, such as Hall elements.
The first and second Hall elements 300-1, 300-2 are coupled to a differential amplifier 310, which comprises a summing block 330, which subtracts the signal B1 from Hall element 300-1 from the signal B2 of Hall element 300-2 to obtain a differential signal dB=B2−B1, which is then amplified by an amplifier 340 by a factor gS1.
The circuit further comprises a further pre-amplifier 350 with a differential direction calculation comprising a further summing block 360 to which all three Hall elements 300-1, 300-2, 300-3 are coupled. The further summing block 360 calculates a difference of the signal B3 provided by Hall element 300-3 and an arithmetic mean value of the signals B2 of Hall element 300-2 and B1 of Hall element 300-1 to obtain a direction signal dBdir=B3−(B2+B1)/2. The further preamplifier 350 further comprises a further amplifier 370, which amplifies the signal dBdir by a factor gd.
In the example shown in
Conventionally, concentrated sensor elements (mono cells) may also be used. However, mono cells may not be able to suppress homogeneous changes in the physical quantity as opposed to differential ones. For instance, a dynamic homogeneous magnetic disturbance-field may eventually not be distinguished from a differential field caused by a moving pole wheel or another wanted magnetic field source. This may lead to a greatly degraded robustness of the sensor in the presence of external disturbances.
The circuit shown in
The Wheatstone bridge 410, which is a full bridge, is coupled in between a terminal for a reference potential 450 and a power supply circuit 460 comprising an operational amplifier 470, which is supplied with a reference potential V_ref provided to the non-inverting input of the operation amplifier 470 and a fed back voltage provided to the inverting input of the operational amplifier 470, which is provided at the output of the operational amplifier 470. As a consequence, a regulated voltage Vbr (bridge voltage) is supplied to the Wheatstone bridge 410.
However, the circuit as shown in
To be more precise, the center GMR sensor element 490 is coupled in between a terminal 500 for the reference potential 500 and a node 510 to which a fixed current source 520 and a further current source 530 are coupled. While the fixed current source 520 provides the basic current to operate the center GMR sensor element 490, the further current source 530 can provide an additional current to compensate for higher order temperature variations.
The node 510 is further coupled to a non-inverting input of a differential amplifier 540 at which the voltage Vcent dropping across the center GMR sensor element 490 is obtainable and provided to the differential amplifier 540. For the center GMR sensor element 490, a non-sensitive reference can be used to obtain a pseudo-differential signal as shown in
At an output of the differential amplifier 540, a signal is obtainable indicative of a magnetic field present at the center GMR sensor element 490 with respect to the fixed voltage present at the node 570 of the voltage divider 550. As a consequence, at the output of the differential amplifier 540, a pseudo-differential signal may be obtainable.
For the sake of completeness, it should be noted that the center GMR sensor element 490 may be arranged along a direction between the so-called left GMR sensor elements comprising the GMR sensor elements 420-1, 420-4 of the Wheatstone bridge 410 and the so-called right sensor elements comprising the GMR sensor elements 420-3 and 420-2 of the Wheatstone bridge 410.
The solution shown in
Only with respect to the center path 480 and its power supply, the circuit shown in
The Wheatstone bridge 410′ of the center path 480 is also coupled to the output of the operational amplifier 470 is also supplied to the Wheatstone bridge 410′ of the center path 480. Therefore, the two Wheatstone bridges 410, 410′ of the speed path 400 and the center path 480, respectively, operate at the same regulated bridge voltage Vbr.
A less attractive point of this solution shown in
A circuit 110 and a sensor 100 according to an embodiment may overcome these drawbacks by generating a reference for the at least one single-ended further sensor element 130 which may also be referred to as the center elements, wherein the reference correlates to the other sensor elements 200 temperature and process drifts. The reference signal (further supply signal SS2) may make a circuit 110 and a sensor 100 according to an embodiment inherently more robust to manufacturing tolerances. Furthermore, it may also suppress the homogeneous presence of a physical quantity like in a differential configuration without the need for an additional Wheatstone bridge. Furthermore, as described below, it may be possible to provide a more favorable phase relation between a speed and a direction signal independent of the sensor element pitch, which may enable a more simple and reliable signal processing algorithm. The direction signals may be obtained from the central path.
For the sake of simplicity only, in the following an embodiment of a GMR-based magnetic sensor for detection of rotational speed and direction of a magnetic pole wheel will be described in more detail. However, it should be noted that this embodiment merely represents an example and can easily be extended to other applications and a more general purpose of embodiments as described above.
Apart from the sensor arrangement 120, which is once again sensitive to the physical quantity, the circuit 110 and the sensor 100 comprise at least one further sensor element 130, which is also implemented in the embodiment shown in
In terms of an orientation with respect to a direction 190 (not shown in
The circuit 110 further comprises a supply circuit 140, which is once again configured to provide the sensor arrangement 120 with a supply signal SS1 comprising a supply voltage controlled by the supply circuit 140 in a closed-loop configuration. Moreover, the supply circuit 140 is also configured to provide the at least one further sensor element 130 with a further supply signal SS2 comprising a further supply current such that the magnitude of the further supply current fulfills a predetermined relationship with the magnitude of the supply current of the supply signal SS1. To be a little more specific, the further supply current of the further supply signal SS2 is essentially proportional to the magnitude of the supply current of the supply signal SS1. To enable this, the supply circuit 140 comprises a current mirror 600, which is configured to provide the further supply signal SS2 with the magnitude of the further current based on the magnitude of the supply current of the supply signal SS1.
To facilitate this, the current mirror 600 comprises a first transistor 610 which is implemented in the embodiment shown in
The drain contacts or terminals of the second transistor 620 forms an output of the supply circuit 140 at which the supply signal SS1 is generated and provided to the sensor arrangement 120. In other words, the two half bridges 210-1, 210-2 of the sensor arrangement 120 are coupled in parallel to the drain terminal of the second transistor 620.
At a drain terminal of the third transistor 630, the further supply signal SS2 is provided and fed into the further sensor element 130 via the second node 180 as described in the context of
When a current is provided into the input branch of the current mirror 600 or, in other words, fed through the first transistor 610, the current mirror 600 replicates a proportional current in both the second and third transistors 620, 630. The proportionality is essentially determined by the layout of the second transistor 620 with respect to the first transistor 610 and of the third transistor 630 with respect to the first transistor 610. For instance, in the case of a MOSFET-implementation, channel width of the respective transistor 610, 620, 630 and ratios based thereon may determine or at least partially influence the proportionality factors of the current mirror 600.
The supply circuit 140 is based on generating a control current CC flowing through the first transistor 610 and a fourth transistor 650, coupled in between the first transistor 610 and a further terminal 240 for the reference potential. To be more precise, a source contact of the fourth transistor 650 is coupled to the terminal 240 for the reference potential, for instance the ground potential, while a drain contact or terminal of the fourth transistor 650 is coupled to the drain terminal of the first transistor 610. A gate terminal of the fourth transistor 650 is coupled to an output of an operational amplifier 660. A non-inverting input of the operational amplifier 660 is provided with a reference voltage indicative of the supply voltage of the supply signal SS1, which is also referred to as bridge voltage Vbr. An inverting input of the operational amplifier is coupled to a first node 150 coupled in between the output of the supply circuit 140 and the sensor arrangement 120 as outlined before.
Hence, the electrical connection between the first node 150 and the inverting input of the operational amplifier 660 forms the feedback circuit 660, which is used to create the regulated or controlled voltage Vbr provided to the sensor arrangement 120. Due to the feedback circuit 660, the supply circuit 140 operates in the closed-loop configuration as described above.
To put it in different terms, the supply circuit 140 comprises a voltage regulator 670, which comprises the first and fourth transistor 610, 650, the operational amplifier 660 and at least partially the feedback circuit 160.
The control current CC as well as the currents flowing through the second and third transistors 620, 630 depend in terms of their magnitude on the physical quantity sensed by the sensor elements 200-1, . . . , 200-4. Therefore, information concerning an average value of the physical value is comprised in the in these currents.
Based on the control current CC flowing through the first transistor 610 and, hence, through the input path of the current mirror 600, the supply current of the supply signal SS1 comprises a magnitude which is based—via the previously-outlined proportionality factor of the transistors 620, 610 involved—based on the magnitude of the control current, while the supply voltage Vbr of the supply signal SS1 is controlled by the voltage regulator 670 comprising the feedback circuit 160.
Moreover, the further current of the further supply signal SS2 is also provided by the supply circuit 140 and its current mirror 600 in response to the control current CC based on the proportionality factor at least partially determined by the transistors 630, 610, involved. However, it is to be noted that the sensing voltage of the further supply signal SS2 is not controlled so that the at least one further sensor element 130 is operated in an open loop mode or configuration.
By employing an implementation based on a control current CC it may be more simple to implement the closed-loop configuration to control the supply voltage of the supply signal SS1. Additionally or alternatively, it may be possible to control the supply current and the further supply current more energy efficiently and/or more precisely than by directly influencing the supply current of the supply signal SS1.
The sensor 100 or—optionally—the circuit 110 further comprises in the embodiment shown in
The differential amplifier 680 of the detection circuit 170 is coupled to the supply circuit 140 to receive a first signal comprising the supply voltage of the supply signal SS1, for instance, from the first node 150. A second input of the differential amplifier 680 may be coupled to the at least one further sensor element 130 to receive a second signal. The second signal may comprise the sensing voltage of the further supply signal SS2, for instance, via the second node 180. The sensing voltage may correspond to or be indicative of a voltage drop across the at least one further sensor element 130. The differential amplifier may then be configured to provide the output signal based on a difference of a supply voltage and the sensing voltage at an output of the differential amplifier 680.
The detection circuit 170 and its differential amplifier 680 along with the at least one further sensor element 130 may, in the embodiment shown in
A basic idea behind the embodiment shown in
In this case, a magnetic field-dependent current is flowing through the further sensor element 130. The current may be dependent on the physical quantity sensed by the sensor elements 200-1, . . . , 200-4 such that information on an average value of the physical quantity may be comprised in this current. A reference voltage for the central path 690 is the supply voltage of the supply signal SS1 of the GMR Wheatstone bridge (sensor arrangement 120).
To illustrate this in more detail, in the following equations valid in a linear region of sensitivity of GMR sensor elements 200, 130 will be derived. The magnetic fields to be sensed, with their homogeneous component, are assumed to be given by:
BR=Bhom(t)+B0 sin(ωt)
BC=Bhom(t)+B0 sin(ωt+φ)
BL=Bhom(t)+B0 sin(ωt+2φ)
The current flowing in the sensor arrangement 120 (Wheatstone bridge) turns out to be:
wherein RGMR(1+αΔT+ . . . ) represents the GMR resistance with its temperature coefficients. S is the GMR sensitivity in the linear region. Using a replica current flowing in the central GMR (further sensor element 130), the sensing voltage at the second node 180 is
As a first result, it is to be noted that the resistance of GMR (with its temperature coefficients) is cancelled out. Moreover, under the assumption that the sensitivity is much lower than 1, the equation above can be rewrite approximating it with the Taylor's series, truncated at the first order:
By neglecting the quadratic contribute (S2 infinitesimal of second order) and subtracting the constant voltage Vbr, which is magnetic field independent, the differential voltage at the central path 690 can be written as:
Substituting the magnetic fields leads to:
It can easily be noticed that the homogeneous field Bhom(t) cancels out. By expanding the half sum term, using the trigonometric formulas, it yields:
Considering the output differential signal of the right-left GMR Wheatstone bridge (sensor arrangement 120), it follows:
By analyzing equation (1.1) and (1.2), it can be concluded:
In the next figures simulation results will be shown, obtained from the implementation of the block level circuit shown in
At first, the GMR cells or sensor elements 200, 130 (right-center-left) are stimulated with small sinusoidal magnetic signals, in order to illustrate an operation in the linear region of sensitivity described before. The transfer function of a GMR sensor element, expressed in percentage resistive variation over magnetic field change, is modeled as depicted in
The sensitivity in the linear range is assumed to be S=0,76%/mT. According to equation (1.1), the central signal and the sensitivity in the central path scale with dependence on the phase shift between right/center (or center/left). The scaling factor is:
S*(1−cos φ) (1.3)
In the following figures φ=120°, φ=90°, φ=60° and φ=45° are used for the phase shift.
In the following figures, saturation effects of the GMR sensor elements are introduced based on the GMR transfer characteristic of
In the following, a short comparison between a more conventional approach and the new topology of central path 690 will be given. Since the new concept employing an embodiment may be implemented using a sensor arrangement 120 differentially measuring (i.e. external homogenous magnetic fields may be suppressed), a comparison with another differential solution will be provided, consisting of a second Wheatstone bridge 410′ in addition to a right-left Wheatstone bridge 410, as, for instance, shown in
The analysis is done for small magnetic signals and large ones, at φ=90° and φ=60°. For completeness, the resulting differential signal of right-left Wheatstone bridge 410 are also provided. As stated in equations (1.1) and (1.2), in the new topology the quadrature between the central path signal and he differential right/left path may be provided independently of the phase shift, so far that an operation in the linear range of GMR sensitivity may be used. This is, in contrast, typically not the case for the right-center Wheatstone bridge solution.
To be more specific,
At large magnetic signals, in case of a phase shift of φ=90°, the central path and the differential path are still in quadrature using the embodiment depicted in
Embodiments may allow, for instance, a magnetic speed sensor to offer a start-stop functionality, which may be referred to as a “0 Hz capability”. In other words, a direction detection at very low speeds during the start-stop procedure may also be possible using an embodiment. Embodiments may, for instance, be used in wheel speed detection applications, to name just one.
As outlined before, conventional, concentrated sensor elements (mono cells) might be used. However, mono cells may not be able to suppress homogeneous changes in the physical quantity as opposed to differential ones. For instance, a dynamic homogeneous magnetic disturbance-field may eventually not be distinguished from a differential field caused by a moving polewheel or another wanted magnetic field source. This may lead to a greatly degraded robustness of the sensor in the presence of external disturbances.
The description and drawings merely illustrate the principles of the invention. It will thus be appreciated that those skilled in the art will be able to devise various arrangements that, although not explicitly described or shown herein, embody the principles of the invention and are included within its spirit and scope. Furthermore, all examples recited herein are principally intended expressly to be only for pedagogical purposes to aid the reader in understanding the principles of the invention and the concepts contributed by the inventor(s) to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions. Moreover, all statements herein reciting principles, aspects, and embodiments of the invention, as well as specific examples thereof, are intended to encompass equivalents thereof.
The methods described herein may be implemented as software, for instance, as a computer program. The sub-processes may be performed by such a program by, for instance, writing into a memory location. Similarly, reading or receiving data may be performed by reading from the same or another memory location. A memory location may be a register or another memory of an appropriate hardware. The functions of the various elements shown in the Figures, including any functional blocks labeled as “means”, “means for forming”, “means for determining” etc., may be provided through the use of dedicated hardware, such as “a former”, “a determiner”, etc. as well as hardware capable of executing software in association with appropriate software. When provided by a processor, the functions may be provided by a single dedicated processor, by a single shared processor, or by a plurality of individual processors, some of which may be shared. Moreover, explicit use of the term “processor” or “controller” should not be construed to refer exclusively to hardware capable of executing software, and may implicitly include, without limitation, digital signal processor (DSP) hardware, network processor, application specific integrated circuit (ASIC), field programmable gate array (FPGA), read only memory (ROM) for storing software, random access memory (RAM), and non-volatile storage. Other hardware, conventional and/or custom, may also be included. Similarly, any switches shown in the Figures are conceptual only. Their function may be carried out through the operation of program logic, through dedicated logic, through the interaction of program control and dedicated logic, the particular technique being selectable by the implementer as more specifically understood from the context.
It should be appreciated by those skilled in the art that any block diagrams herein represent conceptual views of illustrative circuitry embodying the principles of the invention. Similarly, it will be appreciated that any flow charts, flow diagrams, state transition diagrams, pseudo code, and the like represent various processes, which may be substantially represented in computer readable medium and so executed by a computer or processor, whether or not such computer or processor is explicitly shown.
Furthermore, the following claims are hereby incorporated into the Detailed Description, where each claim may stand on its own as a separate embodiment. While each claim may stand on its own as a separate embodiment, it is to be noted that—although a dependent claim may refer in the claims to a specific combination with one or more other claims—other embodiments may also include a combination of the dependent claim with the subject matter of each other dependent claim. Such combinations are proposed herein unless it is stated that a specific combination is not intended. Furthermore, it is intended to include also features of a claim to any other independent claim even if this claim is not directly made dependent to the independent claim.
It is further to be noted that methods disclosed in the specification or in the claims may be implemented by a device having means for performing each of the respective steps of these methods.
Further, it is to be understood that the disclosure of multiple steps or functions disclosed in the specification or claims may not be construed as to be within the specific order. Therefore, the disclosure of multiple steps or functions will not limit these to a particular order unless such steps or functions are not interchangeable for technical reasons.
Furthermore, in some embodiments a single step may include or may be broken into multiple substeps. Such substeps may be included and part of the disclosure of this single step unless explicitly excluded.
Schaffer, Bernhard, Hainz, Simon, Horn, Wolfgang, Michelutti, Alessandro
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